KR20050090018A - Method and system for control of congestion in cdma systems - Google Patents

Abstract

The present invention is a method and system for monitoring and controlling congestion in a CDMA system having multi-user detection capabilities. The method detects congestion in the uplink by calculating noise rise (14) based on user equipment measurements or radio access network measurements. Upon detection of congestion, congestion relieving measures (18) are implemented as needed.

Description

METHOD AND SYSTEM FOR CONTROL OF CONGESTION IN CDMA SYSTEMS

The present invention relates to a code division multiple access (CDMA) system with multi-user detection (MUD) capability, wherein system capacity is defined as intercell interference that has not been eliminated, intercellation between cells that have not been eliminated. Limited by interference associated with interference and noise floor.

In a CDMA system, one factor that limits system capacity is interference. In general, CDMA systems try to produce as little interference as possible. Power control is one method commonly used to keep the interference limit as low as possible. Nevertheless, when trying to support a large number of users in a CDMA system, even if the transmit power is being controlled, the level of interference should not be tolerated.

The concept of CDMA uplink (UL) pole capacity is widely used to assess when a system is congested. This concept is based on the exponential increase in interference due to CDMA systems, ie all interferences beyond the noise floor. Interference due to CDMA systems consists of intracell interference and intercell interference. Intracell interference is interference that occurs in a cell occupied by a user. In contrast, inter-cell interference is interference from all sources outside the cell in which the user is located. The pole capacity is the theoretical maximum capacity under the assumption that the mobile has infinitely available transmission power. The actual dose is usually part of the pole dose. Although this concept is generally applied to any point-to-multipoint CDMA system, the use of MUD in a receiver that eliminates some of the intra-cell interference changes the principle upon which this concept is based, making it impossible to apply.

Therefore, what is needed is a method of estimating congestion in a CDMA system with MUD capability.

The present invention relates to uplink (UL) based on user equipment (UE) measurements or radio access network (RAN) measurements in a code division multiple access (CDMA) system with multiple user detection (MUD) capability. Methods and systems for monitoring and controlling congestion in

For uplink (UL) congestion detection based on UE measurements, the maximum capacity of a normal CDMA system, i.e., a CDMA system without MUD capability, is the total perceived interference versus noise floor represented by Equation 1 below. It can be determined by measuring the noise rise, which is the ratio of the noise floor.

Where total sensed interference is any interference that is not eliminated at the receiver (both intra-cell and inter-cell interference), and the noise floor is any noise that is not related to the system, such as thermal noise, Is the UL load factor.

However, for a CDMA system with MUD capability, the MUD reduces intra-cell interference I _or and increases inter-cell interference I _oc . Therefore, to accurately measure noise rise in a CDMA system with MUD capability, Consideration should be given to the effect of MUD on interference.

To clearly consider the effects of MUD, we define two parameters, one that takes into account I _{or a} decrease and one that increases I _oc. Incorporate into First parameter Represents the average ratio of I _or removed I _or total I _or , and is used when considering I _or reduction. Second parameter Represents the average ratio of the received extra I _oc to the total I _oc and is used in consideration of increasing I _oc . These parameters And Can be measured, calculated or assumed as desired. I _or , I _oc , And By using, the total detection interference considering the effect of MUD is to be.

In a first embodiment of the invention, congestion detection is based on UE measurements. However, UE measurements are limited to I _or in the interference by the system. Therefore, also considering I _oc , according to the following equation (2) Obtain

Where i is a predetermined value representing the ratio of I _oc to I _or , and the sum represents I _or . In the total, N is the number of users in the cell, W is the carrier bandwidth, , And Are the signal-to-noise ratio (E _b / N _o ), bit rate, and activity factor of the j th user, respectively. Multiplying I _or by (1 + i) yields [I _or + I _or (i)], where I _or (i) = I _oc , whereby In consideration of both intra-cell and inter-cell interference. As can be seen from Equation 1, As this goes to 1, the noise rise goes to infinity.

After this is calculated, the noise rise is obtained according to the following equation (3).

1 illustrates a method of monitoring congestion in a UL based on UE measurements in a CDMA system with MUD capability, indicated in its entirety by reference numeral 10.

The method starts at step 12, in which step the UL load factor (i. E. Calculate In step 14, the noise rise is preferably calculated using Equation 3 as described above. The value of noise rise is proportional to congestion. Therefore, in step 16, the value of the noise rise is evaluated to determine whether or not the congestion reduction method is executed. If the value of the noise rise exceeds the predetermined value, a congestion reduction method is executed (step 18). The predetermined value of the noise rise selected to stimulate the congestion alleviation method may be any value. For example, as an example, the predetermined value may be a value between about 6 _dB and about 10 _dB .

On the other hand, if the value of the noise rise is less than or equal to the predetermined value, the method may be restarted from step 12, where the method may be restarted from step 12 with a predetermined time interval. The predetermined time interval can be any amount of time as desired. For example, as an example, the predetermined time interval may be a value between about 3 seconds and about 5 seconds.

In another embodiment of the present invention, UL congestion detection may be based on RAN measurements. In this embodiment, I _oc and I _or are determined by reading the measurements available at the base station (BS). And You can define everything. Therefore, unlike in the first embodiment, without using a predetermined value to find I _oc And noise rise.

More specifically, according to the following equation (4) Obtain

Here, the noise floor is all noise unrelated to the system and the total sense interference includes all interference not removed at the receiver. Since we know what is needed to calculate the total sensed power, The total sensed power can be calculated according to the following equation. Can be calculated.

After this is calculated, the effective noise rise is obtained according to the following equation (6).

FIG. 2 illustrates a method of measuring and avoiding congestion in the UL based on RAN measurements in a CDMA system with MUD capability, indicated in its entirety by reference numeral 50.

In a first step 52, noise rise is measured. Next, in step 54, as described above, preferably using Equation 5 , Where I _oc , I _or , And Is defined by reading the measurements available at the BS. However, as another embodiment, the ratio according to the following equation (7) Can be calculated.

In this embodiment, Can be ignored, eliminating the need to read it from the BS receiver. An additional parameter in equation (7) is identified and defined from the measurements taken at the BS receiver. As an explanation, additional parameters included in Equation 7 are the received code power Rx_Code_Power _i for user i, the spreading factor SF _i for user i, and the number of active codes M in timeslots.

Once this is calculated, in step 56, the noise rise is calculated according to equation (6). As in the embodiment shown in Fig. 1, the value of the noise rise is proportional to congestion. Therefore, in step 58, the value of the noise rise is evaluated to determine whether or not the congestion reduction method is executed. If the value of the noise rise exceeds the predetermined value, a congestion reduction method is executed (step 60). On the other hand, if the value of the noise rise is less than or equal to the predetermined value, the method can be started again from step 52 with a predetermined time interval. As in the embodiment described with reference to FIG. 1, the predetermined value of the noise rise and the time interval may be any value as desired.

The execution of the congestion alleviation method can be accomplished in various ways. For example, by reducing the signal-to-noise ratio (E _b / N _o ) targets of a user, the transmit power of these users can be reduced. However, a drawback of this approach is that these users may experience information transmission errors, which significantly degrades the link quality.

A preferred congestion reduction method is to reduce the data transfer rate of a particular user or users. Users determine their transmit power based on data rate, spreading factor gain, maximum transmit power and path loss. Thus, by reducing the data transfer rate of a particular user (inherently reducing power), the same signal-to-noise ratio can be achieved with the same spreading gain but with less power. Moreover, in a WCDMA TDD system, the reduction in data transfer rate implies that a user may not be able to transmit in a given timeslot, thereby providing an additional benefit of reducing congestion during that timeslot.

The preferred congestion reduction method limits the data transfer rate at the source, so no retransmission is required. The user or users are selected to reduce the data transmission rate in consideration of the transmission power, the reception power, and the service class. These factors are considered for each user and can be considered individually, collectively, or as a specific combination thereof as desired. It is desirable to select the user or users with the highest contribution to interference and the lowest class of service priority as candidates for data rate reduction.

A preferred congestion alleviation method is shown in FIG. 3, the entirety of which is indicated by the reference numeral 100. First, in step 102, step 104, and step 106, transmission power, reception power, and service grade are determined for each user, respectively. Next, in step 108, the contribution to noise rise of each user is calculated. As described, the noise rise may be calculated according to Equation 3 or 6 as desired.

In step 110, the users who collectively have the highest contribution to noise rise and the lowest class of service priority are selected. In determining the selection user, a predetermined weight factor may be used for each parameter. The important point is that any value can be used in the weighting factor so that the influence of priority and contribution to noise on user selection can be adjusted as desired. It may also be desirable to use only one of these parameters, or it may be desirable to use additional parameters such as priority and contribution to noise that may be weighted as desired. The user selection criteria are so flexible that any criterion can be used as long as it can accurately identify users with data transmission rates that can be reduced for congestion reduction. Therefore, for example, the selected user can be determined according to the following equation (8).

In step 112, the data transmission rate of the selected user is reduced. In step 113, the amount of congestion is evaluated to determine whether to reduce congestion. If the reduction in the corresponding noise rise is sufficient to reduce the value of the noise rise below the predetermined value at which congestion is detected, the method may end and continue the congestion monitoring described in connection with FIGS. 1 and 2 (step 114). ). On the other hand, if congestion is not reduced so that the value of the noise rise is less than or equal to the predetermined value, since there is still congestion, the method 100 returns to step 110 or step 102 as desired until the congestion is reduced. Can be continued.

Referring now to FIG. 4, shown is a system 200 for controlling congestion in a UL based on UE measurements. In system 200, UE measurements are used to monitor and control congestion in the UL. System 200 includes at least one UE 202, BS or Node B 214, and wireless network controller 210.

The UE includes a receiver 203 with MUD capability, an I _or measurement device 204, and an I _or signaling device 206. The I _or measurement apparatus 204 measures the amount of interference by the system in the cell in which the UE 202 is currently located using information available from the UE 202. As described above, this kind of interference is referred to as intra-cell interference I _or .

BS or Node B 214 includes a receiver 205 with MUD capability and an I _or signal receiver 208. I _or I _or a measuring device 204, the measurement is transmitted from the I _or signaling device 206 of the UE (202) to the I _or signal receiver 208 of the BS or node B (214). BS or Node B 214 delivers I _or to Radio Network Controller (RNC) 210 that includes Radio Resource Management (RRM) device 212. RRM 212 may process I _or with BS or Node B 214 as needed to obtain the total interference affected by MUD 203, 205. As mentioned above, the total interference is I _or , , And i can be obtained.

Once you get the total interference, Also find the noise rise. If the noise rise exceeds a predetermined value, each user's contribution to the noise rise is measured. Preferably, the transmit power, receive power, and service grade of each user are also measured. If the data transfer rate of the user with the highest contribution to the current noise rise and the lowest class of service is necessary, reduce the overall noise rise until it is below the predetermined value. In other words, if the reduction in the data transfer rate of the user who contributes the most to the noise rise is not enough to reduce the noise rise below a predetermined value, then the contribution of each user to the noise rise is continuously recalculated. Reduces the data transfer rate of the highest user. Alternatively, current user calculations may continue to be used to simply reduce the data transfer rate of the next highest contribution user.

FIG. 5 shows another embodiment of a system for controlling congestion in the UL, indicated in its entirety by reference numeral 300. In system 300, RAN measurements are used to monitor and control congestion at the UL. System 300 includes at least one UE 301, BS or Node B 306, and RNC 308.

The UE 301 includes a receiver 303 with MUD capability. BS or Node B 306 includes a receiver 305 with MUD capability, an I _or measurement device 302, and an I _oc measurement device 304. The BS or Node B 306 forwards I _or and I _oc to a Radio Network Controller (RNC) 308 that includes a Radio Resource Management (RRM) device 310. RRM 310 may process I _or and I _oc with BS or Node B 306 if necessary, to obtain the total interference affected by MUD 303, 305. As mentioned above, the total interference is I _or , I _oc , , Can be obtained using

Once you get the total interference, Also find the noise rise. If the noise rise exceeds a predetermined value, each user's contribution to the noise rise is measured. Preferably, the transmit power, receive power, and service grade of each user are also measured. As described with reference to FIG. 4, if the data transfer rate of the user who has the highest contribution to the current noise rise and the lowest grade of service is necessary, the total noise rise is reduced until it is below a predetermined value.

Although the present invention has been described in detail, those skilled in the art will recognize that various modifications can be made without departing from the scope of the technical idea of the present invention as defined by the appended claims. Could be.

The present invention can detect congestion in the uplink by calculating 14 a noise rise based on user device measurements or radio access network measurements.

1 is a flow chart illustrating a method for monitoring congestion in a UL based on UE measurements in a CDMA system with MUD capability in accordance with an embodiment of the present invention.

2 is a flowchart illustrating a method for monitoring congestion in a UL based on RAN measurements in a CDMA system with MUD capability in accordance with an embodiment of the present invention.

3 is a flow chart illustrating a method for reducing congestion in accordance with an embodiment of the present invention.

4 is a diagram illustrating a system for monitoring and controlling congestion in a UL based on UE measurements in accordance with an embodiment of the present invention.

5 is a diagram illustrating a system for monitoring and controlling congestion in a UL based on RAN measurements in accordance with an embodiment of the present invention.

Claims (18)

A method of controlling congestion in a code division multiple access (CDMA) system having a multi-user detection capability, Calculating a noise rise value indicative of interference in the system based on user device measurements; Monitoring the noise rise value for congestion detection; Execution step of executing the congestion mitigation method upon congestion detection Congestion control method comprising a. The method of claim 1, wherein the user device measurement comprises an intra-cell interference value. The congestion control method of claim 1, wherein the calculating step includes considering an influence of interference on the multi-user detection capability of the CDMA system. 4. The congestion control method of claim 3, wherein the influence of the multi-user detection capability on the interference is a reduction in intracell interference and an increase in intercell interference. The method of claim 1, wherein the congestion reduction method is Determining a service grade for each user; Calculating a contribution to noise rise for each user; Selecting a user with the highest contribution to the current noise rise and the lowest service grade; Reducing the data transmission rate of the selected user. A method of controlling congestion in a code division multiple access (CDMA) system having a multi-user detection capability, A measuring step of measuring a noise floor; Calculating a noise rise value indicative of interference in the system based on radio access network measurements; Monitoring the noise rise value for congestion detection; Execution step of executing the congestion mitigation method upon congestion detection Congestion control method comprising a. 7. The congestion control method of Claim 6, wherein the radio access network measurement includes an intracell interference value and an intercell interference value. 8. The congestion control method of Claim 7, wherein the radio access network measurements are measurements taken at at least one base station in the radio access network. 8. The congestion control method of Claim 7, wherein the radio access network measurements are measurements taken at at least one Node B in the radio access network. 7. The congestion control method of claim 6, wherein the calculating step includes considering the effect of the multi-user detection capability of the CDMA system on interference. 7. The congestion control method of claim 6, wherein the effect of the multi-user detection capability on interference is a reduction in intracell interference and an increase in intercell interference. The method of claim 6, wherein the congestion reduction method, Determining a service grade for each user; Calculating a contribution to noise rise for each user; Selecting a user with the highest contribution to the current noise rise and the lowest service grade; Reducing the data transmission rate of the selected user. A method of controlling congestion in a code division multiple access (CDMA) system having a multi-user detection capability, A measuring step of measuring a noise floor; Calculating a noise rise value in consideration of the influence of the multi-user detection capability on the interference; Monitoring the noise rise value for congestion detection; Execution step of executing the congestion mitigation method upon congestion detection Including; The congestion reduction method, Determining a service grade for each user; Calculating a contribution to noise rise for each user; Selecting a user with the highest contribution to the current noise rise and the lowest service grade; Reducing the data transmission rate of the selected user. A system for controlling congestion in a code division multiple access (CDMA) system having a multi-user detection capability, At least one user device including a receiver having a multi-user detection capability, an intra-cell interference measurement device, and an intra-cell interference signaling device for sending a signal indicative of intra-cell interference to a base station; A base station including a receiver having a multi-user detection capability and an intra-cell interference signal receiver for receiving a signal sent by the intra-cell interference signaling apparatus; A radio network controller having a radio resource management device and controlling congestion based on measurements taken at the user device Congestion control system comprising a. The method of claim 14, wherein the congestion control system, Calculate a noise rise value indicative of interference in the CDMA system; Monitor the noise rise value for congestion detection; By performing the congestion reduction method at the time of congestion detection, A congestion control system that controls congestion. A system for controlling congestion in a code division multiple access (CDMA) system having a multi-user detection capability, At least one user device comprising a receiver having a multi-user detection capability; A base station including a receiver having a multi-user detection capability, an intra-cell interference measuring device, and an inter-cell interference measuring device; A radio network controller having a radio resource management device and controlling congestion based on measurements taken at the base station Congestion control system comprising a. The method of claim 16, wherein the congestion control system, Calculate a noise rise value indicative of interference in the CDMA system; Monitor the noise rise value for congestion detection; By performing the congestion reduction method at the time of congestion detection, A congestion control system that controls congestion. A system for controlling congestion in a code division multiple access (CDMA) system having a multi-user detection capability, At least one user device comprising a receiver having a multi-user detection capability; A base station including a receiver having a multi-user detection capability, an intra-cell interference measuring device, and an inter-cell interference measuring device; A radio network controller having a radio resource management device and controlling congestion based on measurements taken at the base station Including; The congestion, Calculate a noise rise value indicative of interference in the CDMA system; Monitor the noise rise value for congestion detection; By performing the congestion reduction method at the time of congestion detection, The congestion control system being controlled.